Role of apolipoproteins, ABCA1 and LCAT in the biogenesis of normal and aberrant high density lipoproteins.

Panagiotis Fotakis,Shi Su,Vassilis I Zannis

doi:10.7555/jbr.31.20160082

Panagiotis Fotakis, Shi Su + Show 1 more

Open Access

https://doi.org/10.7555/jbr.31.20160082

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Abstract

In this review, we focus on the pathway of biogenesis of HDL, the essential role of apoA-I, ATP binding cassette transporter A1 (ABCA1), and lecithin: cholesterol acyltransferase (LCAT) in the formation of plasma HDL; the generation of aberrant forms of HDL containing mutant apoA-I forms and the role of apoA-IV and apoE in the formation of distinct HDL subpopulations. The biogenesis of HDL requires functional interactions of the ABCA1 with apoA-I (and to a lesser extent with apoE and apoA-IV) and subsequent interactions of the nascent HDL species thus formed with LCAT. Mutations in apoA-I, ABCA1 and LCAT either prevent or impair the formation of HDL and may also affect the functionality of the HDL species formed. Emphasis is placed on three categories of apoA-I mutations. The first category describes a unique bio-engineered apoA-I mutation that disrupts interactions between apoA-I and ABCA1 and generates aberrant preβ HDL subpopulations that cannot be converted efficiently to α subpopulations by LCAT. The second category describes natural and bio-engineered apoA-I mutations that generate preβ and small size α4 HDL subpopulations, and are associated with low plasma HDL levels. These phenotypes can be corrected by excess LCAT. The third category describes bio-engineered apoA-I mutations that induce hypertriglyceridemia that can be corrected by excess lipoprotein lipase and also have defective maturation of HDL. The HDL phenotypes described here may serve in the future for diagnosis, prognoses and potential treatment of abnormalities that affect the biogenesis and functionality of HDL.

Highlights

In this review, we focus on the pathway of biogenesis of HDL, the essential role of apoA-I, ATP binding cassette transporter A1 (ABCA1), and lecithin: cholesterol acyltransferase (LCAT) in the formation of plasma HDL; the generation of aberrant forms of HDL containing mutant apoA-I forms and the role of apoA-IV and apoE in the formation of distinct HDL subpopulations
Using cell culture and in vitro experiments, we investigated the ability of apoA-I mutants to promote ABCA1 mediated efflux of cholesterol and phospholipids and to crosslink to ABCA1
Density gradient ultracentrifugation showed only small amount of the apoA-I in the HDL3 fraction (Fig. 2G), electron microscopy (EM) analysis showed the presence of a small number of HDL size particles (Fig. 2H), and the twodimensional gel electrophoresis showed the presence of small amount of preβ and α4 HDL particles (Fig. 2I). These findings demonstrate that the LCAT treatment failed to convert efficiently the preβ to αHDL particles or to correct this specific defect in the biogenesis of HDL

Summary

Introduction

We focus on the pathway of biogenesis of HDL, the essential role of apoA-I, ATP binding cassette transporter A1 (ABCA1), and lecithin: cholesterol acyltransferase (LCAT) in the formation of plasma HDL; the generation of aberrant forms of HDL containing mutant apoA-I forms and the role of apoA-IV and apoE in the formation of distinct HDL subpopulations. Co-expression of the apoA-I[225-230] mutant and human LCAT corrected the abnormal HDL levels, created normal preβ and αHDL subpopulations and generated spherical HDL particles[60].

Results

Conclusion